Aerospace Medicine and Rehabilitation Laboratory, Faculty of Health and Life Sciences, Northumbria University, Newcastle upon Tyne, United Kingdom.
School of Allied Health Sciences, Griffith University, Nathan Campus, Brisbane, Queensland, Australia.
J Appl Physiol (1985). 2021 Jul 1;131(1):356-368. doi: 10.1152/japplphysiol.00990.2020. Epub 2021 Jun 3.
Exposure to axial unloading induces adaptations in paraspinal muscles, as shown after spaceflights. This study investigated whether daily exposure to artificial gravity (AG) mitigated lumbar spine flattening and muscle atrophy associated with 60-day head-down tilt (HDT) bed rest (Earth-based space analog). Twenty-four healthy individuals participated in the study: 8 received 30-min continuous AG; 8 received 6 × 5-min AG interspersed with rest periods; and 8 received no AG exposure (control group). Magnetic resonance imaging (MRI) of the lumbopelvic region was conducted at baseline (BDC) and at day 59 of HDT (HDT59). Longitudinal relaxation time (T1)-weighted images were used to assess morphology of the lumbar spine (spinal length, intervertebral disk angles, disk area) and volumes of the lumbar multifidus (LM), lumbar erector spinae (LES), quadratus lumborum (QL), and psoas major (PM) muscles from L/L to L/S vertebral levels. A chemical shift-based two-point lipid/water Dixon sequence was used to evaluate muscle composition. Results showed that spinal length and disk area increased ( < 0.05); intervertebral disk angles ( < 0.05) and muscle volumes of LM, LES, and QL reduced ( < 0.01); and lipid-to-water ratio for the LM and LES muscles increased ( < 0.01) after HDT59 in all groups. Neither of the AG protocols mitigated the lumbar spinae deconditioning induced by HDT bed rest. The increase in lipid-to-water ratio in LM and LES muscles indicates an increased relative intramuscular lipid concentration. Altered muscle composition in atrophied muscles may impair lumbar spine function after body unloading, which could increase injury risk to vulnerable soft tissues. This relationship needs further investigation. This study presents novel insights into the morphological adaptations occurring in the lumbar spine after 60-day head-down bed rest and the potential role of artificial gravity (AG) to mitigate them. Results demonstrated no protective effect of AG protocols used in this study. In atrophied paraspinal muscles, the ratio of lipids versus intramuscular water increased in the postural lumbar muscles, which could impair muscle function during upright standing. These findings have relevance for future space explorations.
轴向卸载会引起脊柱旁肌肉的适应性变化,这在太空飞行后已经得到证实。本研究旨在探讨日常暴露于人工重力(AG)是否可以减轻与 60 天头低位卧床(地球模拟太空)相关的腰椎变平化和肌肉萎缩。24 名健康个体参与了这项研究:8 名接受 30 分钟连续 AG;8 名接受 6×5 分钟 AG 间歇休息;8 名未接受 AG 暴露(对照组)。在基线(BDC)和头低位卧床 59 天时(HDT59)对腰骨盆区域进行磁共振成像(MRI)检查。纵向弛豫时间(T1)加权图像用于评估腰椎(脊柱长度、椎间盘角度、椎间盘面积)和腰椎多裂肌(LM)、腰椎竖脊肌(LES)、腰方肌(QL)和腰大肌(PM)的体积,从 L/L 到 L/S 椎体水平。化学位移双点脂质/水 Dixon 序列用于评估肌肉成分。结果表明,脊柱长度和椎间盘面积增加(<0.05);椎间盘角度(<0.05)和 LM、LES 和 QL 肌肉体积减少(<0.01);LM 和 LES 肌肉的脂质/水比值增加(<0.01)在所有组中均在 HDT59 后。两种 AG 方案均不能减轻 HDT 卧床休息引起的腰椎失健。LM 和 LES 肌肉中脂质/水比值的增加表明肌肉内相对脂质浓度增加。萎缩肌肉中肌肉成分的改变可能会使脊柱在失载后功能受损,从而增加对脆弱软组织的损伤风险。这种关系需要进一步研究。本研究为 60 天头低位卧床后腰椎发生的形态学适应性变化以及人工重力(AG)减轻这些变化的潜在作用提供了新的见解。结果表明,本研究中使用的 AG 方案没有保护作用。在脊柱旁萎缩肌肉中,脊柱旁肌肉中脂质与肌肉内水的比例增加,这可能会在直立站立时损害肌肉功能。这些发现与未来的太空探索有关。
